Robert Scott Trowbridge has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).

Abstract: A process and apparatus integrate a first 3D object model with a second 3D object model to generate an integrated 3D printable model. The first 3D object model models a first object that is passive. The second 3D object model models an electrical power source receptacle that operably connects to an electrical power source that provides electrical power for operation of the first object. The process and apparatus print a 3D object based upon the 3D model.

Abstract: A method for controlling vehicle progression along a ride path of an amusement park ride. The method includes receiving inputs from a passenger of a vehicle on the ride path and processing the received inputs to determine a vehicle state change. The method includes determining a present or predicted vehicle state and comparing the present or predicted vehicle state with constraints defined by a dynamic boundary associated with the vehicle. The method includes issuing vehicle control commands to a drive assembly to implement the vehicle state change if it complies with the constraints. The dynamic boundary is moved logically along the ride path at a nominal to define a set of boundaries for movement of the vehicle along the ride path. The vehicle state change may be a change that causes the vehicle to travel at a speed differing from the dynamic boundary while remaining within the dynamic boundary.

Abstract: A system for flock-based control of a plurality of unmanned aerial vehicles (UAVs). The system includes UAVs each including a processor executing a local control module and memory accessible by the processor for use by the local control module. The system includes a ground station system with a processor executing a fleet manager module and with memory storing a different flight plan for each of the UAVs. The flight plans are stored on the UAVs, and, during flight operations, each of the local control modules independently controls the corresponding UAV to execute its flight plan without ongoing control from the fleet manager module. The fleet manager module is operable to initiate flight operations by concurrently triggering initiation of the flight plans by the multiple UAVs. Further, the local control modules monitor front and back end communication channels and, when a channel is lost, operate the UAV in a safe mode.

Abstract: There is provided a system and method for controlling a tracking device to follow a location of a performer on a stage. The tracking device may comprise a lighting fixture such as a high output video projector or an automated mechanical moving light such as a DMX lighting fixture to provide a followspot, or a microphone to record audio from a particular performer. The method comprises capturing a video feed of the stage using a camera, presenting the video feed on a display of a control device, receiving input data indicating a position of the performer in the video feed, translating the input data into the location of the performer on the stage, and adjusting the tracking device to follow the location of the performer on the stage. The control device thereby provides lighting operators with an intuitive interface readily implemented using cost effective commodity hardware.

Abstract: A process integrates object geometry data of an object and data describing an electronic component that is embeddable within the object to generate a printable model. The process also prints an object based upon the integrated printable model. A computing apparatus, e.g., a computing device, a printer, etc., uses a processor to perform the integration and at least one printer head to print the object. The process partially prints the object and then retrieves the electronic component specified by the integrated 3D printable model. The process then operably connects the electronic component to the partially complete object and subsequently completes printing the object. The process can print mechanical receivers for the electronic component or install prefabricated mechanical receivers.

Abstract: A process and apparatus integrate a first 3D object model with a second 3D object model to generate an integrated 3D printable model. The first 3D object model models a first object that is passive. The second 3D object model models an electrical power source receptacle that operably connects to an electrical power source that provides electrical power for operation of the first object. The process and apparatus print a 3D object based upon the 3D model.

Abstract: An apparatus comprises a puppet device. The apparatus also comprises a control mechanism operably connected to the puppet device to control movement of the puppet device. The control mechanism comprises a material having a material index of refraction that substantially matches a fluid index of refraction of a fluid in which the puppet device and the control device are positioned such that the control mechanism is rendered substantially invisible. Further, another apparatus comprises an object. The apparatus also comprises an actuator that is operably connected to the object and moves in a fluid environment based upon movement of a control mechanism that interacts with the actuator in the fluid environment, the control mechanism comprising a material having a material index of refraction that substantially matches a fluid index of refraction to render the control mechanism substantially invisible in the fluid environment.

Abstract: A system for flock-based control of a plurality of unmanned aerial vehicles (UAVs). The system includes UAVs each including a processor executing a local control module and memory accessible by the processor for use by the local control module. The system includes a ground station system with a processor executing a fleet manager module and with memory storing a different flight plan for each of the UAVs. The flight plans are stored on the UAVs, and, during flight operations, each of the local control modules independently controls the corresponding UAV to execute its flight plan without ongoing control from the fleet manager module. The fleet manager module is operable to initiate flight operations by concurrently triggering initiation of the flight plans by the multiple UAVs. Further, the local control modules monitor front and back end communication channels and, when a channel is lost, operate the UAV in a safe mode.

Abstract: A system for performing an aerial display. The system includes a plurality of UAVs each including a propulsion device and a display payload, and the system includes a ground station system with a processor executing a fleet manager module and memory storing a different flight plan and a set of display controls for the UAVs. Then, wherein, during a display time period, the UAVs concurrently execute the flight plans through operation of the propulsion devices and operate the display payloads based on the display controls. The display payloads each include a lighting assembly and a light controller. The output light is one of a two or more colored light streams, and each of the display payloads further may include a light diffuser with the output light being directed onto a surface of the light diffuser. The light diffuser may include a light diffusing screen extending about the lighting assembly.

Abstract: A system for flock-based control of a plurality of unmanned aerial vehicles (UAVs). The system includes UAVs each including a processor executing a local control module and memory accessible by the processor for use by the local control module. The system includes a ground station system with a processor executing a fleet manager module and with memory storing a different flight plan for each of the UAVs. The flight plans are stored on the UAVs, and, during flight operations, each of the local control modules independently controls the corresponding UAV to execute its flight plan without ongoing control from the fleet manager module. The fleet manager module is operable to initiate flight operations by concurrently triggering initiation of the flight plans by the multiple UAVs. Further, the local control modules monitor front and back and communication channels and, when a channel is lost, operate the UAV in a safe mode.

Abstract: A method for controlling vehicle progression along a ride path of an amusement park ride. The method includes receiving inputs from a passenger of a vehicle on the ride path and processing the received inputs to determine a vehicle state change. The method includes determining a present or predicted vehicle state and comparing the present or predicted vehicle state with constraints defined by a dynamic boundary associated with the vehicle. The method includes issuing vehicle control commands to a drive assembly to implement the vehicle state change if it complies with the constraints. The dynamic boundary is moved logically along the ride path at a nominal to define a set of boundaries for movement of the vehicle along the ride path. The vehicle state change may be a change that causes the vehicle to travel at a speed differing from the dynamic boundary while remaining within the dynamic boundary.

Abstract: A method for controlling vehicle progression along a ride path of an amusement park ride. The method includes receiving inputs from a passenger of a vehicle on the ride path and processing the received inputs to determine a vehicle state change. The method includes determining a present or predicted vehicle state and comparing the present or predicted vehicle state with constraints defined by a dynamic boundary associated with the vehicle. The method includes issuing vehicle control commands to a drive assembly to implement the vehicle state change if it complies with the constraints. The dynamic boundary is moved logically along the ride path at a nominal speed to define a set of boundaries for movement of the vehicle along the ride path. The vehicle state change may be a change that causes the vehicle to travel at a speed differing from the dynamic boundary while remaining within the dynamic boundary.

Abstract: A method for controlling vehicle progression along a ride path of an amusement park ride. The method includes receiving inputs from a passenger of a vehicle on the ride path and processing the received inputs to determine a vehicle state change. The method includes determining a present or predicted vehicle state and comparing the present or predicted vehicle state with constraints defined by a dynamic boundary associated with the vehicle. The method includes issuing vehicle control commands to a drive assembly to implement the vehicle state change if it complies with the constraints. The dynamic boundary is moved logically along the ride path at a nominal to define a set of boundaries for movement of the vehicle along the ride path. The vehicle state change may be a change that causes the vehicle to travel at a speed differing from the dynamic boundary while remaining within the dynamic boundary.

Abstract: A system for performing an aerial display. The system includes a plurality of UAVs each including a propulsion device and a display payload, and the system includes a ground station system with a processor executing a fleet manager module and memory storing a different flight plan and a set of display controls for the UAVs. Then, wherein, during a display time period, the UAVs concurrently execute the flight plans through operation of the propulsion devices and operate the display payloads based on the display controls. The display payloads each include a lighting assembly and a light controller. The output light is one of a two or more colored light streams, and each of the display payloads further may include a light diffuser with the output light being directed onto a surface of the light diffuser. The light diffuser may include a light diffusing screen extending about the lighting assembly.

Abstract: A system for performing an aerial display. The system includes a plurality of unmanned aerial vehicles (UAVs) and a ground control system with a processor executing a fleet manager module and with memory storing a different flight plan for each of the UAVs. The system further includes a marionette with a body and articulatable appendages attached to the body. The body and appendages are supported with tether lines extending between the marionette and the UAVs. Then, during a display time period, the UAVs concurrently execute the flight plans to position and articulate the marionette within a display air space. In some embodiments, the UAVs each is a multicopter, and each of the multicopters includes a local controller operating to move the multicopter through a series of way points defined by the flight plan associated with the multicopter.

Abstract: A system for performing an aerial display. The system includes a plurality of UAVs each including a propulsion device and a display payload, and the system includes a ground station system with a processor executing a fleet manager module and memory storing a different flight plan and a set of display controls for the UAVs. Then, wherein, during a display time period, the UAVs concurrently execute the flight plans through operation of the propulsion devices and operate the display payloads based on the display controls. The display payloads each include a lighting assembly and a light controller. The output light is one of a two or more colored light streams, and each of the display payloads further may include a light diffuser with the output light being directed onto a surface of the light diffuser. The light diffuser may include a light diffusing screen extending about the lighting assembly.

Abstract: A system for presenting an aerial display over an audience of spectators. The system includes a plurality of unmanned aerial vehicles (UAVs) and a plurality of flexible projection screens. Each of the screens is supportable in a display air space by the UAVs. The system includes a ground control system with a processor executing a fleet manager module and with memory storing a different flight plan for each of the UAVs. During operation during a display time period, the UAVs execute the flight plans to move and to position the flexible projection screens within the display air space. The flexible projection screens each may include a mesh body configured to have low wind resistance and to provide a projection surface for reflecting light. The system may include a projector projecting light onto the projection surface of at least one of the flexible projection screens during the display time period.

Abstract: A system for performing an aerial display. The system includes a plurality of UAVs each including a propulsion device and a display payload, and the system includes a ground station system with a processor executing a fleet manager module and memory storing a different flight plan and a set of display controls for the UAVs. Then, wherein, during a display time period, the UAVs concurrently execute the flight plans through operation of the propulsion devices and operate the display payloads based on the display controls. The display payloads each include a lighting assembly and a light controller. The output light is one of a two or more colored light streams, and each of the display payloads further may include a light diffuser with the output light being directed onto a surface of the light diffuser. The light diffuser may include a light diffusing screen extending about the lighting assembly.

Abstract: A system for performing an aerial display. The system includes a plurality of unmanned aerial vehicles (UAVs) and a ground control system with a processor executing a fleet manager module and with memory storing a different flight plan for each of the UAVs. The system further includes a marionette with a body and articulatable appendages attached to the body. The body and appendages are supported with tether lines extending between the marionette and the UAVs. Then, during a display time period, the UAVs concurrently execute the flight plans to position and articulate the marionette within a display air space. In some embodiments, the UAVs each is a multicopter, and each of the multicopters includes a local controller operating to move the multicopter through a series of way points defined by the flight plan associated with the multicopter.

Abstract: A system for presenting an aerial display over an audience of spectators. The system includes a plurality of unmanned aerial vehicles (UAVs) and a plurality of flexible projection screens. Each of the screens is supportable in a display air space by the UAVs. The system includes a ground control system with a processor executing a fleet manager module and with memory storing a different flight plan for each of the UAVs. During operation during a display time period, the UAVs execute the flight plans to move and to position the flexible projection screens within the display air space. The flexible projection screens each may include a mesh body configured to have low wind resistance and to provide a projection surface for reflecting light. The system may include a projector projecting light onto the projection surface of at least one of the flexible projection screens during the display time period.